DRIVER PERSONALIZED CLIMATE CONDITIONING
An HVAC system for a vehicle includes a skin temperature sensor for measuring an actual skin temperature of the driver and a cabin temperature sensor for measuring an actual cabin temperature of ambient air within the passenger cabin. A controller module stores a target cabin temperature, wherein the controller module controls the HVAC system according to a first error between the target cabin temperature and the actual cabin temperature. The actual cabin temperature is filtered according to a first time constant. A personalization module stores a target skin temperature, wherein the personalization module determines an offset to be applied to the target cabin temperature according to a second error between the target skin temperature and the actual skin temperature. The actual skin temperature is filtered according to a second time constant longer than the first time constant.
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BACKGROUND OF THE INVENTIONThe present invention relates in general to heating, ventilating, and air conditioning (HVAC) systems for transportation vehicles, and, more specifically, to personalized control of an HVAC system based on skin temperature of an occupant or driver of the vehicle.
HVAC systems control the climate in transportation vehicles such as automobiles in order to maintain thermal comfort of the vehicle occupants. Typically, a blower passes air through heat exchangers and delivers conditioned air to various points within the passenger cabin. Warm air may be provided by a heater core obtaining heat from coolant flowing in a combustion engine, for example. Cool air may be obtained from a conventional air conditioning system having a motor driven compressor and an evaporator.
The simplest climate control systems in motor vehicles provide the occupant with direct control of the intensity of heating or cooling, the operating speed of the blower, and the relative amount of air flow going to different registers. This requires the user to continually monitor and adjust the climate control settings in order to remain comfortable.
Automatic temperature control systems have also been introduced wherein a feedback control system monitors ambient air temperature within the passenger compartment and automatically adjusts blower speed and heater core or air conditioning operation to maintain a desired temperature setting. In some vehicles, multiple zones have been implemented with separate automatic temperature control with individual target temperature settings being made for each zone.
The foregoing types of HVAC systems only indirectly control the actual skin temperature of an occupant. Because skin temperature is a better indicator of actual occupant comfort, systems have been investigated for regulating HVAC system operation based on the skin temperature of the vehicle occupants. However, the thermodynamic environment in a vehicle interior is complex, as are the relationships between various HVAC control settings and the resulting effect on skin temperature of different occupants. Therefore, previous systems have been relatively complex and not cost effective.
SUMMARY OF THE INVENTIONThe present invention obtains personalized climate control that is tailored to one occupant in the vehicle, such as the driver. Instead of directly attempting to regulate the skin temperature of the occupant, certain adjustments are made to the target cabin temperature for controlling the HVAC so that operation is only partially controlled in response to skin (i.e., body) temperature. Certain limitations are placed on the adjustments in order to ensure stable system operation.
In one aspect of the invention, apparatus is provided in a transportation vehicle operated by a driver within a passenger cabin comprising skin temperature sensor for measuring an actual skin temperature of the driver and a cabin temperature sensor for measuring an actual cabin temperature of ambient air within the passenger cabin. An HVAC system provides heated and cooled air flow into the passenger cabin. A controller module stores a target cabin temperature, wherein the controller module controls the HVAC system according to a first error between the target cabin temperature and the actual cabin temperature. The actual cabin temperature is filtered according to a first time constant. A personalization module stores a target skin temperature, wherein the personalization module determines an offset to be applied to the target cabin temperature according to a second error between the target skin temperature and the actual skin temperature. The actual skin temperature is filtered according to a second time constant longer than the first time constant.
Referring now to
The present invention builds upon the EATC system of
A system of the present invention is shown in greater detail in
In order to obtain skin temperature measurements of the driver, a pair of infrared temperature sensors 32 and 33 is mounted on steering wheel 21. Heated or cooled air flow is provided onto the driver from various registers, including a register 35.
Control apparatus for performing the present invention is shown in greater detail in
Driver personalization function 40 receives various temperature measurements including skin temperature 43, ambient internal (i.e., cabin) temperature 44, ambient external air temperature 45, and a preview temperature 46. Preview temperature 46 may correspond to upcoming external temperature conditions based on 1) current or future temperature measurements at a destination toward which the vehicle is being driven, or 2) a short-term temperature forecast for the vicinity of the vehicle. These preview temperatures may be received from a remote service provider via the wireless communication system. Based on known models relating various temperature conditions to the personal feeling of comfort according to a person's skin temperature, personalization function 40 derives a recommended skin target temperature based on known physical/perceptual models.
Using a target skin temperature derived from
The signal processing and decision making performed in
where CT is actual cabin temperature, αCT is the filter gain between 0 and 1 which defines the first time constant, BT is actual skin temperature, αBT is the filter gain that defines the second time constant, and k is an index. The first error is determined in accordance with a formula:
CTerr(k)=CTtar(k)−
where CTerr is the first error and CTtar is the target cabin temperature (i.e., that is used by the EATC as the feedback target). The second error is determined in accordance with a formula:
BTerr(k)=BTtar(k)−
where BTerr is the second error and BTtar is the target skin temperature. An updated target cabin temperature (i.e., after incrementing index k by one) is determined in accordance with a formula:
CTtar(k)=CTtar(k−1)+K1BTerr(k)
where K1 is the tunable gain factor for a normalized gain factor between 0 and 1. The magnitude of BTerr is applied if the tunable normalized K1 range is between −1 to 1 to provide appropriate directional offsets to the cabin temperature.
A rule-base is provided for the value of gain factor K1 which is designed to limit the amount of change at each iteration and to prevent changes during times when the cabin temperature error is more than a threshold difference (e.g., 5° F.). One embodiment for the rule base for the invention is shown as a normalized surface plot in
CTtar(k)=CTtar(k−1)+K1|BTerr(k)|
The magnitudes for the cabin temperature error and body temperature error are shown with respect to a normalized scale between 1 and −1 representing thresholds within which the personalization function is allowed to operate. Near the thresholds, the value of K is zero in order to prevent operation of the personalization function. For example, at high values of cabin temperature error along regions 64 and 65 of surface 60 the value of K1 approaches zero. Likewise, when the body temperature error is close to zero, surface 60 is at a zero value as shown at region 66. When the value of cabin temperature error is close to zero, but body temperature error is between upper and lower thresholds, increasingly larger values of gain factor K1 are represented as shown in regions 67 and 68.
Instead of a mapping, the controller can alternatively use a numerical relationship for determining the gain factor. Such a relationship can be stated generally as K1=f(CTerr, BTerr). Suitable equations defining this function are designed according to the desired properties for a particular vehicle, but would produce a gain factor similar to the mapping shown in
delta—CTtar(k)=K1BTerr(k)
for normalized gain factors between 0 and 1,
and
delta—CTtar(k)=K1|BTerr(k)|
with a normalized K1 range between −1 to 1. So that the personalization function does not impair overall performance of the temperature control system and to ensure stability of operation, the offset is further modified according to the following limits:
where δthres is an upper-bound for CTerr, βthres is an lower-bound for CTerr, αthres is an upper-bound for BTerr, and λthres is an lower-bound for BTerr. The thresholds prevent the personalization function from introducing modifications whenever either of the errors are too small or too big, thereby ensuring stability and avoiding undesirable interactions.
In order to obtain robust skin temperature measurements, detection regions of the infrared temperature sensors mounted on the steering wheel may be provided as shown in
The temperature measurements are evaluated to ensure that the sensor obtaining the better skin temperature measurement is utilized as shown in
As shown in
Claims
1. Apparatus in a transportation vehicle occupied by a person within a passenger cabin, comprising:
- a skin temperature sensor for measuring an actual skin temperature of the person;
- a cabin temperature sensor for measuring an actual cabin temperature of ambient air within the passenger cabin;
- an HVAC system for providing heated and cooled air flow into the passenger cabin;
- a controller module storing a target cabin temperature, wherein the controller module controls the HVAC system according to a first error between the target cabin temperature and the actual cabin temperature, wherein the actual cabin temperature is filtered according to a first time constant; and
- a personalization module storing a target skin temperature, wherein the personalization module determines an offset to be applied to the target cabin temperature according to a second error between the target skin temperature and the actual skin temperature, wherein the actual skin temperature is filtered according to a second time constant longer than the first time constant.
2. The apparatus of claim 1 wherein the offset is zero when the first error between the target cabin temperature and the filtered actual cabin temperature is greater than a first threshold.
3. The apparatus of claim 1 wherein the offset is determined in response to the second error multiplied by a gain factor.
4. The apparatus of claim 3 wherein the gain factor is determined in response to corresponding magnitudes of the first error and the second error.
5. The apparatus of claim 3 further comprising a map for correlating corresponding magnitudes of the first error and the second error with a value for the gain factor.
6. The apparatus of claim 1 wherein the filtered actual cabin temperature is determined in accordance with a formula where CT is actual cabin temperature, αCT is the filter gain between 0 and 1 which defines the first time constant, and k is an index.
- CTk=αCT CTk-1+(1−αCT)CTk
7. The apparatus of claim 1 wherein the filtered actual skin temperature is determined in accordance with a formula where BT is actual skin temperature, αBT is the filter gain between 0 and 1 which defines the second time constant, and k is an index.
- BTk=αBT BTk-1+(1−αBT)BTk
8. The apparatus of claim 1 wherein the filtered actual cabin temperature is determined in accordance with a formula where CT is actual cabin temperature, αCT is the first time constant, and k is an index; where BT is actual skin temperature and αBT is the second time constant; where CTerr is the first error and CTtar is the target cabin temperature; where BTerr is the second error and BTtar is the target skin temperature; and where K1 is the gain factor.
- CTk=αCT CTk-1+(1−αCT)CTk
- wherein the filtered actual skin temperature is determined in accordance with a formula BTk=αBT BTk-1+(1−αBT)BTk
- wherein the first error is determined in accordance with a formula CTerr(k)=CTtar(k)− CTk
- wherein the second error is determined in accordance with a formula BTerr(k)=BTtar(k)− BTk
- wherein an updated target cabin temperature is determined in accordance with a formula CTtar(k)=CTtar(k−1)+K1BTerr(k)
9. The apparatus of claim 1 wherein the skin temperature sensor is comprised of an infrared sensor mounted in a steering wheel of the vehicle and directed toward a face of the person.
10. The apparatus of claim 1 wherein the skin temperature sensor is comprised of first and second infrared sensors mounted in a steering wheel of the vehicle and directed toward a left-side and a right-side of a face of the person, respectively, and wherein the personalization module compares temperature measurements from the infrared sensors with the measured actual cabin temperature to determine the actual skin temperature.
11. The apparatus of claim 1 further comprising a user interface, wherein the target cabin temperature includes a manual user setting selected via the user interface.
12. The apparatus of claim 1 further comprising a user interface, wherein the target skin temperature includes a manual user setting selected via the user interface.
13. The apparatus of claim 12 wherein the personalization module calculates a recommended skin temperature and displays the recommended skin temperature via the user interface.
14. The apparatus of claim 13 further comprising a wireless communication device for obtaining a preview external air temperature, wherein the recommended skin temperature is calculated in response to the preview external air temperature.
15. The apparatus of claim 1 wherein the controller module and the personalization module are integrated in a programmable microcontroller.
16. A method of controlling heated and cooled air flow from an HVAC system into a passenger cabin of a transportation vehicle occupied by a person, comprising the steps of:
- measuring an actual skin temperature of the person;
- measuring an actual cabin temperature of ambient air within the passenger cabin;
- storing a target cabin temperature;
- filtering the actual cabin temperature according to a first time constant;
- controlling the HVAC system according to a first error between the target cabin temperature and the filtered actual cabin temperature;
- storing a target skin temperature;
- filtering the actual skin temperature according to a second time constant longer than the first time constant; and
- determining an offset for updating the target cabin temperature according to a second error between the target skin temperature and the filtered actual skin temperature.
17. The method of claim 16 wherein the offset is zero when the first error between the target cabin temperature and the filtered actual cabin temperature is greater than a first threshold.
18. The method of claim 16 wherein the offset is determined in response to the second error multiplied by a gain factor.
19. The method of claim 18 further comprising the step of determining the gain factor in response to corresponding magnitudes of the first error and the second error.
20. The method of claim 19 wherein a map correlates corresponding magnitudes of the first error and the second error with a value for the gain factor.
21. The method of claim 16 further comprising the steps of:
- determining an external air temperature outside the passenger cabin;
- calculating a recommended skin temperature in response to the external air temperature and the actual cabin temperature; and
- displaying the recommended skin temperature to the person via a user interface.
22. The method of claim 16 further comprising the steps of:
- receiving a preview external air temperature via a wireless communication system;
- calculating a recommended skin temperature in response to the preview external air temperature and the actual cabin temperature; and
- displaying the recommended skin temperature to the person via a user interface.
23. A method of providing personalized climate control of a person in a seated position within a transportation vehicle, comprising the steps of:
- collecting a first temperature measurement from a first infrared sensor directed toward a first region of the seated position corresponding to the left side of the face of the person;
- collecting a second temperature measurement from a second infrared sensor directed toward a second region of the seated position corresponding to the right side of the face of the person;
- measuring an actual cabin temperature of ambient air within the passenger cabin;
- comparing each of the first and second temperature measurements with the actual cabin temperature;
- selecting the one of the first or second temperature that deviates the most from the actual cabin temperature as an actual skin temperature; and
- controlling ventilation applied to the person based on the actual skin temperature.
Type: Application
Filed: Mar 27, 2012
Publication Date: Oct 3, 2013
Patent Grant number: 9643471
Applicant: FORD GLOBAL TECHNOLOGIES, LLC (DEARBORN, MI)
Inventors: Kwaku O. Prakah-Asante (Commerce Twp., MI), Jialiang Le (Canton, MI), Manoharprasad K. Rao (Novi, MI), Gary S. Strumolo (Beverly Hills, MI)
Application Number: 13/430,776
International Classification: B60H 1/32 (20060101); B60H 1/00 (20060101);